Camera module

ABSTRACT

A camera module generally provided in a mobile terminal. The camera module includes a lens unit which is configured to accommodate at least one lens. An actuator unit is configured to fix the lens unit, and a base which is fixed by an adhesive to the bottom of the actuator. A printed circuit board (PCB) to which the base is fixed for thereby supplying electric power to the actuator unit. Either a corner of an outer side of the bottom of the actuator unit or a corner of an outer side of the top of the base is tapered.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present application is a Continuation of co-pending U.S. patentapplication Ser. No. 14/485,167 filed on Sep. 12, 2014, which claimspriority under 35 U.S.C. §119 to Korean Application Nos. 10-2013-0110223filed on Sep. 13, 2013, and 10-2013-0133495 and 10-2013-0133491 eachfiled on Nov. 5, 2013, whose entire disclosures are hereby incorporatedby reference.

BACKGROUND 1. Field

The present application relates to a camera module, and in particular toa camera module which is generally installed at a mobile terminal.

2. Background

In recent years, a variety of mobile terminals are widely used, andfaster wireless internet services become available. The customers ofsuch mobile terminals are demanding various advanced functions. To meetsuch demands, a variety of value-added devices are increasinglyinstalled at the mobile terminals. Among such value-added devices, thereis a camera module configured to photograph a predetermined object in aform of photo or motion picture and store such an image data and editand transmit based on the necessity of a user.

The compact-sized camera module is increasingly used at a variety ofmultimedia devices such as a note pad type personal computer, a cameraphone, a PDA, a smart toy, etc. and is also used at an image inputdevice such as an information terminal of a monitoring camera or a videotape recorder. As the pixel sizes of the sensor applied to the cameramodule decrease and the height of the module lowers, a camera modulewith a new mounting structure has become a serious issue, which aims tosecure high durability in the mechanical components of the cameramodule, more specifically, in a tilt or shift-related component of alens optic axis along with a good management against the input ofimpurities.

In the related camera module, the engagement of a cover can encasing alens barrel and an actuator unit and a base disposed to install an IRfilter on a printed circuit board (PCB) is implemented by an engagingprotrusion which protrudes from a lower side surface of the cover canand an engaging groove formed at an upper side surface of the base andcorresponding to the engaging protrusion. In such an engaging structure,the manufactured camera module may have a slight allowance due to theformations of the engaging groove of the base and the engagingprotrusion of the cover can. The above-described engaging method whereinsuch an allowance occurs may not be proper for the use at the cameramodule which requires good optic axis alignment.

In order to possibly solve such a problem, the cover can and the basemay be fixed using an adhesive. Since a relatively smaller area betweenthe cover can and the base is fixed using an adhesive, the adhesiveflowing out from the cover can needs to be eliminated, causing increasedtime and cost in terms of product productivity.

For the adhesive, a thermosetting adhesive which hardens by heat and aUV-hardened adhesive which hardens by UV may be used. In case that thethermosetting adhesive is used, the camera module is thermally treatedin the oven. A predetermined material and component which aredenaturized by means of heat during the above-mentioned heat treatmentshould be used, which causes increased cost. When the UV-hardenedadhesive is used, it is difficult to properly scan for hardening theadhesive due to the compact size of the camera module and a portionwhere the adhesive is applied is too small. Such a problem related tothe scanning of UV also occurs when performing a main adhering procedureusing a thermosetting adhesive after a temporal adhering is performedusing the UV-hardened adhesive.

If the adhesive flows inside of the cover can, the adhesive maycontaminate other inside components such as an IR filter causingproblems with the reliability and quality of products. Such a problemmay occur when the fixing force by the adhesive is not enough, and theadhesive may be peeled off due to external impacts, resulting in poordurability of the product.

BRIEF DESCRIPTION OF THE DRAWINGS

The embodiments will be described in detail with reference to thefollowing drawings in which like reference numerals refer to likeelements wherein:

FIG. 1 is a vertical cross sectional view illustrating a camera moduleaccording to an exemplary embodiment of the present application;

FIG. 2 is a perspective view illustrating a base according to anexemplary embodiment of FIG. 1;

FIG. 3 is a vertical cross sectional view illustrating a camera moduleaccording to another exemplary embodiment of the present application;

FIG. 4 is a plane view illustrating a base according to an exemplaryembodiment of FIG. 3;

FIG. 5 is a partial perspective view illustrating a base according to anexemplary embodiment of FIG. 3; and

FIG. 6 is a partial perspective view illustrating a base of a cameramodule according to another exemplary embodiment of the presentapplication.

DETAILED DESCRIPTION

The terms used herein the specification should be understood as beingsame as the meanings that those who skilled in the art understand unlessotherwise stated, and when the terms used in the specification collidewith the common meaning of the corresponding term, such terms should becomply with the definitions of the specification.

FIG. 1 is a vertical cross sectional view illustrating a camera moduleaccording to an exemplary embodiment of the present application, andFIG. 2 is a perspective view illustrating a base according to anexemplary embodiment of FIG. 1. The camera module 100 includes a lensunit 120, an actuator unit 140, an image sensor 160 and a base 180.There may be further provided an IR filter 50 or a cover can 110.

The cover can 110 is configured to encase the lens unit 120 and theactuator unit 140 and defines an exterior of the camera module 100. Sucha cover can 110 protects the inside components from external impacts andprevents the introduction of external contaminants. The cover can 110also protects the components of the camera module from externalelectronic interferences which occurs due to the use of a cellularphone. The cover can 110 may be made from a metallic material.

The cover can 110 may be fixed in place by a yoke unit 143 itself or maybe fixed by molding the yoke unit 143 at an inner side. It is apparentthat the exterior of the cover can 110 may be changed based on thecomponent accommodating environments inside of the camera. The cover can110 may further comprise a first engaging member 113, a stopper 114, anupper side surface 111 and a side surface 112.

The printed circuit board 170 is provided at a lower side of the base180. Such a printed circuit board 170 is configured to mount a varietyof devices disposed for driving the camera module 100 and supplyingelectric power to drive the actuator unit 140.

The image sensor 160 may be mounted on the printed circuit board 170 tobe located based on at least one lens housed in the lens unit 120 and anoptic axis direction (O). Such an image sensor 160 is configured toconvert an optical signal of a predetermined object incident through thelens into an electrical signal.

The lens unit 120 is housed in the actuator unit 140 and is disposed inplace at a portion where corresponds to the image sensor 160. The lensunit 120 is configured to house at least one lens (not shown). The lensunit 120 may be a lens barrel which is formed as a plurality of lensesare arranged along an optic axis.

The actuator unit 140 comprises a bobbin 144 which is engaged along anouter circumferential surface of the lens barrel 120 for thereby fixingthe lens barrel 120. The actuator unit 140 serves to fix the lens unit120 inside of the bobbin 144 and adjust the focus of a predeterminedimage by moving the lens unit 120.

The actuator unit 140 may be configured such that the camera module 100can perform an auto focusing function or may be configured such that thecamera module 100 can perform optical image stabilization (OIS). If theactuator unit 140 is an auto focusing actuator (A.F), there may beprovided a voice coil motor may be provided, but not limited thereto.Alternatively, the camera may be a fixed focusing type (F.F).

In case of the auto focusing type, as illustrated in FIGS. 1 and 3, theactuator unit 140 comprises a coil unit 142 provided on an outercircumferential surface of the bobbin 144, a magnet unit 141 which isprovided at a portion corresponding to the coil unit 142 in the actuatorunit 140, and a yoke unit 143 configured to fix the magnet unit 141. Theyoke unit may define exterior look of the actuator, instead of the covercan 110.

Electric current is applied to the coil unit 141 as a driving signalapplied by the printed circuit board 170, and the bobbin 144 secured tothe lens unit 120 moves upward or downward along the optic axisdirection (O) by means of the magnet unit 141 which cooperates with thecoil unit 141.

For the optic image stabilization (OIS) type or function, at least onelens or a lens barrel move in a direction vertical with respect to theoptic axis. FIGS. 1 and 3 illustrates an occasion wherein such movementis not considered, but since part of the construction illustrated as theexamples of A.F type in the drawings may be shared, such constructionmay be described with reference to the drawings. The actuator unit 140comprise a first coil unit 142 provided on an outer circumferentialsurface of the bobbin 144, a magnet unit 141 provided at a portioncorresponding to the outer circumferential surface of the first coilunit 142, a second coil unit (not shown) which is mounted on the printedcircuit board disposed at the base 180 to correspond to the lower sidesurface of the magnet unit 141, and a yoke unit 143 configured to fixthe magnet unit 141.

In case of the optical image stabilization (OIS) type, the second coilunit may be a FPCB (not shown) provided on the upper side surface of thebase 180. Considering the compactness of the camera module 100, i.e.,considering lowering the height in an x-axis direction which is theoptic axis direction, the second coil unit may be a circularly patternedcoil. The pattern coil may be directly formed at the printed circuitboard or the pattern coil may be previously formed and then may beattached to the printed circuit board. On the upper surface of the base130, a hall sensor unit (not shown) is provided at a portioncorresponding to the magnet unit 141. The hall sensor unit is configuredto sense the electric voltage applied to detect the movements of themagnet unit 41 and the intensity and phase of the electric current whichflows through the coil and is provided to precisely control the actuatorunit in cooperation with the FPCB.

The first coil unit 142 serves to move upward and downward (z-axisdirection) the lens unit in the optic axis direction, and the secondcoil unit serves to move the lens unit in the x-axis direction and/ory-axis direction which is a direction perpendicular to the optic axisdirection.

The first coil unit 142 and the second coil unit may be configured todirectly receive the electric power from the printed circuit board orreceive electric power by means of the printed circuit board (FPCB orPCB) since the printed circuit board (FPCB or PCB) provided as thesecond coil unit on top of the base 180 is electrically connected to theprinted circuit board. Since the detailed method for supplying electricpower to the first coil unit and the second coil unit is apparent to oneof ordinary skill based on the present disclosure, the detaileddescriptions thereof will be omitted.

The hall sensor unit is disposed on a straight line along with themagnet unit so as to detect any displacement in the x-axis and y-axisdirections. Such a hall sensor unit is provided in closer proximity tothe second coil unit rather than the magnet unit 141, but consideringthat the intensity of the magnetic field formed at the magnets ishundreds times larger than the intensity of the electromagnetic fieldformed at the coils, the effects of the second coil unit may not beconsidered important in terms of the detection of the movements of themagnet unit 141. In addition, the hall sensor unit may be disposed atthe center of the circle of the circular type pattern coil or at theprinted circuit board near the center where the pattern coil is notprovided.

The IR filter 150 is provided between the image sensor 160 and the lensunit 120. The IR filter 150 is an infrared ray filter, but for example aflat plate shaped optic filter such as an imaging surface protectingcover glass, a cover glass, etc.

In order to dispose the IR filter 150, the camera module 100 comprises abase 180 between the cover can 110 and the printed circuit board 170.The IR filter 150 may be engaged at a hollow portion, namely a secondopening 181 a of a second engaging member 180 which is to be explainedafterward, formed at the center of the base 180.

In the above-described construction, the present application may havethe following optic axis (O) alignment of the camera module.

Referring to FIG. 1, the lens unit 120 and the bobbin 144 may beimplemented without any thread engagement. Following the trends ofrequiring high performance camera modules, since a more strict errorrange in the optic axis (O) alignment is demanded, the thread freeengaging method seems to be more effective rather than the thread-basedengaging method.

The above-described thread free engaging method is implemented such away that the lens unit 120 is inserted into the hollow portion of thebobbin 144 from top or bottom, and the optic axis alignment isperformed. When the bobbin 144 is positioned where it is fixed at thelens unit 120, an adhesive is applied on the contacting surfaces betweenthe bobbin 144 and the lens unit 120, thus forming an adhesive layer200, by means of which the bobbin 144 and the lens unit 120 may bestably fixed.

The above-mentioned adhesive may be a thermosetting epoxy or a UV epoxywhich hardens when it is exposed to heat or UV, provided that when thethermosetting epoxy is used, the bobbin 144 and the lens unit 120 maysway when the bobbin 144 and the lens unit 120 which have been alignedon the optic axis (O) move into the oven, so it is first bonded andhardened with the UV epoxy and then it is additionally bonded andhardened with thermosetting epoxy.

Alternatively the adhesive may be applied in a circular shape on thewhole contacting surfaces between the bobbin 144 and the lens unit 120or may be applied in a form of dots or lines at regular intervals.

The lens unit 120 may further comprise at its top a flange unit 121protruding upward. The flange unit 121 is provided at the lens unit 120so as to prevent part of the inward penetration of the adhesive andserves to make easier the optic axis (O) alignment of the bobbin 144 andthe lens unit 120. The flange unit may be designed to have a stopperfunction when the lens barrel is assembled to the bobbin so that thelens barrel may position at a predetermined design distance with respectto the image sensor.

The bobbin 144 comprises a top portion 144 a having an inner diametersame as or slightly larger than an outer diameter of the flange unit 121of the lens unit 120, a slanted portion 144 b which extends from a lowerside of the top portion 144 a and is slanted in an axis direction, and abottom portion 144 c which extends from a lower side of the slantedportion 144 b and has an inner diameter same as or slightly larger thanan outer diameter of the lens unit 120.

The lens unit 120 is inserted from the top portion 144 a of the bobbin144 and moves downward and is finally accommodated into the bottomportion 144 c. The downward movement of the lens unit 120 may be limitedbecause the flange unit 121 of the lens unit 120 is caught on theslanted portion 144 b of the bobbin 144.

The slanted portion 144 b of the bobbin 144 and the flange unit 121 ofthe lens unit 120 may have stopper functions of limiting the downwardmovements when the lens unit 120 is assembled to the bobbin 144. Anadhesive accommodation space may be secured at top of the flange unit insuch a way to limit part of the inward penetration of the adhesive.

The exemplary embodiments of the present application which will bedescribed below may be applied where the engaging method of the bobbin144 and the lens unit 120 is a thread free engaging method as well aswhere the camera module has a thread-based engaging method.

In order to obtain better optic axis (O) alignment, the actuator unit140 and the base 180 may be implemented as follows. The cover can 110may comprise an upper side surface 111 having at its center an exposurehole 111 a through which a lens of the lens unit 120 is exposed, and aside surface 112 which extends from the upper side surface 111. Theactuator unit 140 may further comprise a first engaging member 113 whichis vertically formed at its lower end in an optic axis direction of thelens and has at its center a first opening 113 a.

The first engaging member 113 may be formed separately from the covercan 110 or the actuator unit 140, but it may be preferable that thefirst engaging member 113 is formed in an integrated structure in termsof the durability.

There is further provided a stopper 114 which has a third opening withthe same diameter as or larger than the diameter of the bobbin so as tolimit the downward movements of the bobbin 144. Such a stopper 114 maybe integrally formed with the first engaging member 113 and supports thebottom portion 144 c of the bobbin 144 for thereby limiting the downwardmovements of the bobbin 144.

Meanwhile, the base 180 comprises a second engaging member 181 fixed atthe first engaging member 113 by the adhesive layer 200 wherein a secondopening 181 a communicating with the first opening 113 a is formed atthe center, and a support member 182 which is bent and extend downwardfrom the second engaging member 181. The support member 182 is mountedon the printed circuit board 170.

The second engaging member 181 may be provided separately from thesupport member 182, but it is preferred that the second engaging member181 is integrated with the base 180 in terms of durability.

The exemplary embodiment of the present application may provide bettereffects in terms of external impacts and product finish quality becausethe first engaging member 113 and the second engaging member 181 areengaged over relatively wider area using the adhesive layer 200.

The adhesive layer 200 used to adhere the actuator unit 140 and the base180 may be a thermosetting epoxy or UV epoxy-based adhesive which tendto harden when it is exposed to heat or UV, provided that when thethermosetting epoxy is used, the bobbin 144 and the lens unit 120 mayswing when the bobbin 144 and the lens unit 120 which have been alignedon the optic axis (O) move into the oven, so it may be implemented usingthe UV epoxy.

The adhesive may be applied on the whole contacting surfaces of thefirst engaging member 113 and the second engaging member 181 or may beapplied in a form of dots or lines at regular intervals.

A tapered unit 183 which is chamfered may be provided where the secondengaging member 181 and the support member 182 meet each other, e.g., atthe interconnection portion in an attempt to make sure that more UV canbe scanned to the adhesive to make easier the applying of the adhesiveand make quicker the hardening of the adhesive outside of the device.The tapered unit 183 may be formed by rounding, not by chamfering. Notillustrated in the drawings, the tapered unit 183 is not formed at thecontacting surface of the second engaging member 181 and the supportmember. Instead of the formation of the tapered unit 183, the corner ofthe first engaging member 113 may be chamfered or tapered or rounded.

In order to prevent the degradation of the function of the camera module100 when the applied adhesive penetrates into the imaging components,more specifically, into the IR filter 150, the image sensor 160,accommodated inside of the base 180, the exemplary embodiment of thepresent application may further comprise a recess unit 184 on the upperside surface of the second engaging member 181 so as to prevent themovements of the adhesive in the direction of the IR filter 150.

The recess unit 184 may be provided on the upper surface of the base180, namely, on the second engaging member 181. The recess unit 184 maybe formed in a ring-shaped recess surrounding the second opening 181 aof the base 180. The recess 184 serves to prevent the overflow of theadhesive toward the IR filter 150 in such a way to accommodate the overinputted adhesive when forming the adhesive layer 200.

The second opening 181 a of the base 180 is sealed by means of the IRfilter 150. To make easier the engagement of the IR filter 150 andprevent the inward inputs of the adhesive, a vertically protrudingprotruding portion 185 is provided near the second opening and on anupper side surface of the second engaging member 181. In this case, onthe upper side surface of the second engaging member 181, the IR filter150 surface-contacts with an inner circumferential surface of theprotruding portion 185. In the upper side surface of the second engagingmember 181, the recess unit 184 may be provided outside of theprotruding portion 185.

The protruding portion 185 may be a ring shaped wall body or a dam whichencases the surrounding of the second opening 181 a of the base 180.Since such a wall body or dam serves to prevent the adhesive flowingtoward the IR filter 150, it may be preferable that the height of thewall body or the dam is higher than the IR filter. Both the protrudingportion 185 and the recess unit 184 serve to limit the adhesive fromflowing toward the IR filter 150, which operations may be obtained insuch a way that the recess unit 184 gathers the adhesive inside ofitself and the protruding portion 185 blocks the inflow of the adhesive.Referring to FIGS. 1 and 6, with regard to the arrangement of theprotruding portion 185 and the recess unit 184, the protruding portion185 is provided in closer proximity to the IR filter 150, and the recessunit 184 is provided relatively farther; however alternatively theirpositions may be reversed.

As illustrated in FIGS. 1 and 3, as a window formed larger than theeffective image region of the image sensor 160, a second opening 181 amay be formed near the center of the base 180. The second opening 181 ahas an inner circumferential surface with a constant surface area due tothe thickness of the base 180.

When the light reflected on the inner circumferential surface istransmitted to the image sensor 160, an error such as flare may occursin the image. In order to prevent such an error, it needs to provide thesecond opening 181 a whose inner circumferential surface does notreflect any light. Since the protrusion 185 is a wall body or a damwhich is surrounded by the second opening 181 a, it may be utilized toblock the light which is incident toward the inner circumferentialsurface of the second opening 181 a or absorb the light which isreflected on the inner circumferential surface of the second opening 181a.

The protrusion 180 may be provided at any place as long as the innercircumferential surface of the second opening 181 a absorbs thereflection light or there is a shade by means of which light is nottransmitted to the inner circumferential surface of the second opening181 a. The protruding portion 185 may be formed at the upper surface ofthe base 180, and more specifically, on the surface facing the cover can110 and the lens unit 120. It may be preferable that the protrudingportion 185 has a no-gloss black color so as to well absorb the light.For this, the material of the base 180 may also have a no-gloss blackcolor or it is possible to paint for light absorption on the protrudingportion 185 of the base formed through injection molding.

The adhesive layer 200 fixes the first engaging member 113 and thesecond engaging member 181. If the lower surface of the first engagingmember 113 or the upper surface of the second engaging member 181 issleek, adhering force may be deteriorated. In order to improve theabove-mentioned problems, as illustrated in FIG. 3, a strengthreinforcing grooves 184 a may be formed at the upper surface of thesecond engaging member 181.

Referring to FIGS. 4 and 5, the strength reinforcing grooves 184 a maybe formed in the shape of diagonal lines on the upper surface of thesecond engaging member 181 of the base 180. The strength reinforcinggrooves 184 a may be formed in the shape of zigzag lines on the uppersurface of the second engaging member 181 of the base 180.Alternatively, it may be formed in a variety of shapes. The strengthreinforcing grooves 184 a may provide a good engaging force againsthorizontal external force because part of the adhesive applied so as tofix the base 180 and the engaging member 113 of the cover can 110 isinputted and hardens.

The strength reinforcing grooves 184 a are formed in close proximity tothe protrusion 185, but alternatively, it may be formed spaced apartfrom the protruding portion 185. The strength reinforcing grooves 184 amay be provided together with the recess unit 184. FIG. 6 illustratesthe above occasion. It may be preferable that the strength reinforcinggrooves 184 a are formed father than the recess unit 184 from the IRfilter 150 because the adhesive is allowed to penetrate into thestrength reinforcing grooves 184 a, but it needs to greatly prevent thepenetration of the adhesive into the recess unit 184.

Instead of the formation on the upper surface of the second engagingmember 181, the strength reinforcing grooves 184 a may be additionallyformed at the lower surface of the first engaging member 113 togetherwith the formation on the upper surface of the second engaging member181. In the later case, the strength reinforcing grooves (not shown)formed at the first engaging member 113 is formed in the shape ofdiagonal lines crossing the strength reinforcing grooves 184 a of thebase 180, by means of which it is more advantageous to maintain engagingforce with respect to horizontal external force.

The present exemplary embodiment of the present application makes itpossible to obtain good optic axis alignment and is effective to enhancethe reliability and productivity of the product by preventing the insideand outside flows of the adhesive.

Accordingly, the present application is made in an effort to improve theabove-described problems. It is an object of the present application toprovide a camera module which is configured in a structure capable ofscanning enough UV so as to harden an adhesive while fixing, using anadhesive, a cover can and a base.

It is another object of the present application to provide a cameramodule which makes it possible to prevent other components from beingcontaminated by an adhesive which may penetrate inside of the cover can.

It is further another object of the present application to provide acamera module which is capable of enhancing an engaging force of anadhesive.

The other objects, specific advantages and new features of the presentapplication will be apparent by means of the following detaileddescriptions and exemplary embodiments related to the accompanyingdrawings.

To achieve the above objects, there is provided a camera module,comprising a lens unit which is configured to accommodate at least onelens; an actuator unit which is configured to fix the lens unit; a basewhich is fixed by an adhesive to the bottom of the actuator; and aprinted circuit board (PCB) to which the base is fixed for therebysupplying electric power to the actuator unit, wherein either a cornerof an outer side of the bottom of the actuator unit or a corner of anouter side of the top of the base is tapered.

In the camera module according to the present application, the actuatorunit comprises a first engaging member at the center of which a firstopening is formed, and the base comprises a second engaging member atthe center of which a second opening is formed and which is fixed by theadhesive to the first engaging member, and a support member which isbent from the second engaging member and extends downwardly, and aconnection portion interconnecting the second engaging member and thesupport member is chamfered for thereby forming a tapered portion.

In the camera module according to the present application, the actuatorunit comprises a first engaging member at the center of which a firstopening is formed, and the base comprises a second engaging member atthe center of which a second opening is formed and which is fixed by theadhesive to the first engaging member, and a support member which isbent from the second engaging member and extends downwardly, and aconnection portion interconnecting the second engaging member and thesupport member is rounded for thereby forming a tapered portion.

In the camera module according to the present application, there ispreferably further provided a protruding portion which is integral withthe base and protrudes for thereby preventing the adhesive from enteringinto the insides of the actuator unit and the base.

In the camera module according to the present application, there isfurther provided an IR (Infrared) filter which is installed at thecenter of the base. Here, the protruding portion is preferably formed ina ring shape around the IR filter. In addition, the protruding portionpreferably has a height higher than the thickness of the IR filter. Theprotruding portion is made from a no-gloss black color material or theprotruding portion is painted in a no-gloss black color.

In the camera module according to the present application, the basecomprises a plurality of strength reinforcing grooves at either an upperside surface of the base or at a lower end surface of the actuator unit.The plurality of the strength reinforcing grooves is preferably formedin the shape of diagonal lines. The plurality of the strengthreinforcing grooves is formed in the shape of zigzag lines.

In the camera module according to the present application, the actuatorunit comprises a first engaging member at the center of which a firstopening is formed, and the base comprises a second engaging member atthe center of which a second opening is formed and which is fixed by theadhesive to the first engaging member, and the strength reinforcinggrooves are formed either at a lower surface of the first engagingmember or at an upper surface of the second engaging member. At thistime, when the strength reinforcing grooves are formed at both sides ofthe actuator unit and the base, the strength reinforcing grooves of theboth side are arranged to cross each other.

In the camera module according to the present application, the actuatorunit comprises a bobbin which is configured to fix the lens unit; a coilunit which is provided at an outer circumferential surface of thebobbin; a magnet unit which is provided at a portion corresponding tothe coil unit; and a yoke unit which is configured to fix the magnetunit.

According to the present application, a UV-hardened adhesive may bequickly hardened in such a way that a tapered configuration is formed atan outer corner of a lower side of an actuator unit or at an outercorner of an upper side of a base, and UV may be scanned into a spaceobtained by means of the tapered configuration.

Also, the present application is characterized in that even when theamount of the adhesive applied between the actuator unit and the base islarger than expected, the surplus amount of the adhesive can beaccommodated in the recess unit. Albeit there being a help of the recessunit, if the adhesive is still larger in amount, such surplus adhesivemay not overflow the protruding portion. So, it is possible to preventthe inside components of the actuator unit or the base from beingcontaminated by the adhesive, while enhancing the durability and qualityof products.

In the present application, since the strength reinforcing grooves areformed at the upper surface of the base and the lower surface of theactuator unit, and part of the adhesive penetrates into the strengthreinforcing groove, the durability of the product may be enhanced thanksto the enhanced engaging force with the cover can.

Any reference in this specification to “one embodiment,” “anembodiment,” “example embodiment,” etc., means that a particularfeature, structure, or characteristic described in connection with theembodiment is included in at least one embodiment of the invention. Theappearances of such phrases in various places in the specification arenot necessarily all referring to the same embodiment. Further, when aparticular feature, structure, or characteristic is described inconnection with any embodiment, it is submitted that it is within thepurview of one skilled in the art to effect such feature, structure, orcharacteristic in connection with other ones of the embodiments.

Although embodiments have been described with reference to a number ofillustrative embodiments thereof, it should be understood that numerousother modifications and embodiments can be devised by those skilled inthe art that will fall within the spirit and scope of the principles ofthis disclosure. More particularly, various variations and modificationsare possible in the component parts and/or arrangements of the subjectcombination arrangement within the scope of the disclosure, the drawingsand the appended claims. In addition to variations and modifications inthe component parts and/or arrangements, alternative uses will also beapparent to those skilled in the art.

What is claimed is:
 1. A camera module, comprising: a printed circuitboard (PCB); an image sensor disposed on the PCB; a base disposed on anupper surface of the PCB; an actuator unit disposed over the base andcomprising a first engaging member; a lens disposed over the PCB andcoupled to the actuator unit; an adhesive disposed between the base andthe first engaging member, a filter disposed on the base between theimage sensor and the lens, wherein the base includes a taper portiondisposed along at least a circumferential surface of the base andinclined downward toward the outer side of the base, and a protrusionportion disposed on inner side of the taper portion and protruded froman upper surface of the base, and a recess portion disposed between thetaper portion and the protrusion portion and recessed from the uppersurface of the base, wherein a lateral surface of the filter is coveredwith a protrusion portion protruded from the upper surface of the base.2. The camera module of claim 1, wherein the protrusion portioncomprising; a first inclined surface located in upper end and inclineddownward toward the outer side of the base.
 3. The camera module ofclaim 1, wherein the recess portion comprising: a floor surface; a firstlateral surface extending upward from the floor surface; and a secondlateral surface extending upward from the floor surface, and disposed oninner side of the first lateral surface, wherein the first lateralsurface includes a second inclined surface inclined downward toward theinner side of the base.
 4. The camera module of claim 1, wherein thetaper portion is chamferedly or roundly formed.
 5. The camera module ofclaim 1, the filter installed at the center of the base, and theprotrusion portion formed in a ring shape around the filter.
 6. Thecamera module of claim 1, wherein the protrusion portion has a heighthigher than the thickness of the filter.
 7. The camera module of claim1, wherein the protrusion portion is made from a no-gloss black colormaterial.
 8. The camera module of claim 1, wherein the protrusionportion is painted in a no-gloss black color.
 9. The camera module ofclaim 1, wherein the base comprises a plurality of reinforcing groovesat the upper surface of the base.
 10. The camera module of claim 9,wherein the plurality of the reinforcing grooves is formed in the shapeof diagonal lines.
 11. The camera module of claim 9, wherein theplurality of the reinforcing grooves is formed in the shape of zigzaglines.
 12. The camera module of claim 9, wherein the plurality of thereinforcing grooves extends from the recess portion to an outer side ofthe base.
 13. The camera module of claim 9, wherein the plurality of thereinforcing grooves is arranged in parallel with each other.
 14. Thecamera module of claim 1, wherein the actuator unit further comprises: abobbin disposed on the lens; and a yoke unit disposed on the magnetunit.
 15. An optical apparatus, comprising: a printed circuit board(PCB); an image sensor disposed on the PCB; a base disposed on an uppersurface of the PCB; an actuator unit disposed over the base andcomprising a first engaging member; a lens disposed over the PCB andcoupled to the actuator unit; an adhesive disposed between the base andthe first engaging member, a filter disposed on the base between theimage sensor and the lens, wherein the base includes a taper portiondisposed along at least a circumferential surface of the base andinclined downward toward the outer side of the base, and a protrusionportion disposed on inner side of the taper portion and protruded fromthe upper surface of the base, and a recess portion disposed between thetaper portion and the protrusion portion and recessed from the uppersurface of the base, wherein a lateral surface of the filter is coveredwith a protrusion portion protruded from the upper surface of the base.